# 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.

# Common Lisp: Lisp as God intended it to be used (that is, with LOOP)

``````(defun fact (n)
(loop for i from 1 to n
for acc = 1 then (* acc i)
finally (return acc)))
``````

Now, if someone can come up with a version based on FORMAT...

-

# Common Lisp: FORMAT (obfuscated)

Okay, so I'll give it a try myself.

``````(defun format-fact (stream arg colonp atsignp &rest args)
(destructuring-bind (n acc) arg
(format stream
"~[~A~:;~*~/format-fact/~]"
(1- n)
acc
(list (1- n) (* acc n)))))

(defun fact (n)
(parse-integer (format nil "~/format-fact/" (list n 1))))
``````

There has to be a nicer, even more obscure FORMAT-based implementation. This one is pretty straight-forward and boring, simply using FORMAT as an IF replacement. Obviously, I'm not a FORMAT expert.

-

AWK

``````#!/usr/bin/awk -f
{
result=1;
for(i=\$1;i>0;i--){
result=result*i;
}
print result;
}
``````
-
``````#Language: T-SQL, C#
#Style: Custom Aggregate
``````

Another crazy way would be to create a custom aggregate and apply it over a temporary table of the integers 1..n.

``````/* ProductAggregate.cs */
using System;
using System.Data.SqlTypes;
using Microsoft.SqlServer.Server;

[Serializable]
[SqlUserDefinedAggregate(Format.Native)]
public struct product {
private SqlDouble accum;
public void Init() { accum = 1; }
public void Accumulate(SqlDouble value) { accum *= value; }
public void Merge(product value) { Accumulate(value.Terminate()); }
public SqlDouble Terminate() { return accum; }
}
``````

``````create assembly ProductAggregate from 'ProductAggregate.dll' with permission_set=safe -- mod path to point to actual dll location on disk.

create aggregate product(@a float) returns float external name ProductAggregate.product
``````

create the table (there should be a built-in way to do this in SQL -- hmm. a question for SO?)

``````select 1 as n into #n union select 2 union select 3 union select 4 union select 5
``````

then finally

``````select dbo.product(n) from #n
``````
-
``````#Language: T-SQL
#Style: Big Numbers
``````

Here's another T-SQL solution -- supports big numbers in a most Rube Goldbergian manner. Lots of set-based ops. Tried to keep it uniquely SQL. Horrible performance (400! took 33 seconds on a Dell Latitude D830)

``````create function bigfact(@x varchar(max)) returns varchar(max) as begin
declare @c int
declare @n table(n int,e int)
declare @f table(n int,e int)

set @c=0
while @c<len(@x) begin
set @c=@c+1
insert @n(n,e) values(convert(int,substring(@x,@c,1)),len(@x)-@c)
end

-- our current factorial
insert @f(n,e) select 1,0

while 1=1 begin
declare @p table(n int,e int)
delete @p
-- product
insert @p(n,e) select sum(f.n*n.n), f.e+n.e from @f f cross join @n n group by f.e+n.e

-- normalize
while 1=1 begin
delete @f
insert @f(n,e) select sum(n),e from (
select (n % 10) as n,e from @p union all
select (n/10) % 10,e+1 from @p union all
select (n/100) %10,e+2 from @p union all
select (n/1000)%10,e+3 from @p union all
select (n/10000) % 10,e+4 from @p union all
select (n/100000)% 10,e+5 from @p union all
select (n/1000000)%10,e+6 from @p union all
select (n/10000000) % 10,e+7 from @p union all
select (n/100000000)% 10,e+8 from @p union all
select (n/1000000000)%10,e+9 from @p
) f group by e having sum(n)>0

set @c=0
select @c=count(*) from @f where n>9
if @c=0 break
delete @p
insert @p(n,e) select n,e from @f
end

-- decrement
update @n set n=n-1 where e=0

-- normalize
while 1=1 begin
declare @e table(e int)
delete @e
insert @e(e) select e from @n where n<0
if @@rowcount=0 break

update @n set n=n+10 where e in (select e from @e)
update @n set n=n-1 where e in (select e+1 from @e)
end

set @c=0
select @c=count(*) from @n where n>0
if @c=0 break
end

select @c=max(e) from @f
set @x=''
declare @l varchar(max)
while @c>=0 begin
set @l='0'
select @l=convert(varchar(max),n) from @f where e=@c
set @x=@x+@l
set @c=@c-1
end
return @x
end
``````

Example:

``````print dbo.bigfact('69')
``````

returns:

``````171122452428141311372468338881272839092270544893520369393648040923257279754140647424000000000000000
``````
-

# Javascript:

``````factorial = function( n )
{
return n > 0 ? n * factorial( n - 1 ) : 1;
}
``````

I'm not sure what a Factorial is but that does what the other programs do in javascript.

-

# Ruby: Iterative

``````def factorial(n)
(1 .. n).inject{|a, b| a*b}
end
``````

# Ruby: Recursive

``````def factorial(n)
n == 1 ? 1 : n * factorial(n-1)
end
``````
-

``````factorial n = product [1..n]
``````
-

# Eiffel

``````
class
APPLICATION
inherit
ARGUMENTS

create
make

feature -- Initialization

make is
-- Run application.
local
l_fact: NATURAL_64
do
l_fact := factorial(argument(1).to_natural_64)
print("Result is: " + l_fact.out)
end

factorial(n: NATURAL_64): NATURAL_64 is
--
require
positive_n: n >= 0
do
if n = 0 then
Result := 1
else
Result := n * factorial(n-1)
end
end

end -- class APPLICATION
``````
-

# befunge-93

``````                                    v
>v"Please enter a number (1-16) : "0<
,:             >\$*99g1-:99p#v_.25*,@
^_&:1-99p>:1-:!|10          <
^     <
``````

An esoteric language by Chris Pressey of Cat's Eye Technologies.

-

# J

``````   fact=. verb define
*/ >:@i. y
)
``````
-

## Smalltalk, memoized

Define a method on Dictionary

``````Dictionary >> fac: x
^self at: x ifAbsentPut: [ x * (self fac: x - 1) ]
``````

usage

`````` d := Dictionary new.
d at: 0 put: 1.
d fac: 24
``````
-

## Smalltalk, 1-Liner

``````(1 to: 24) inject: 1 into: [ :a :b | a * b ]
``````
-

## Smalltalk, using a closure

``````    fac := [ :x | x = 0 ifTrue: [ 1 ] ifFalse: [ x * (fac value: x -1) ]].

Transcript show: (fac value: 24) "-> 620448401733239439360000"
``````

NB does not work in Squeak, requires full closures.

-

Perl (Y-combinator/Functional)

``````print sub {
my \$f = shift;
sub {
my \$f1 = shift;
\$f->( sub { \$f1->( \$f1 )->( @_ ) } )
}->( sub {
my \$f2 = shift;
\$f->( sub { \$f2->( \$f2 )->( @_ ) } )
} )
}->( sub {
my \$h = shift;
sub {
my \$n = shift;
return 1 if \$n <=1;
return \$n * \$h->(\$n-1);
}
})->(5);
``````

Everything after 'print' and before the '->(5)' represents the subroutine. The factorial part is in the final "sub {...}". Everything else is to implement the Y-combinator.

-

# Mathematica: non-recursive

``````fact[n_] := Times @@ Range[n]
``````

Which is syntactic sugar for `Apply[Times, Range[n]]`. I think that's the best way to do it, not counting the built-in `n!`, of course. Note that that automatically uses bignums.

-

Common Lisp version:

``````(defun ! (n) (reduce #'* (loop for i from 2 below (+ n 1) collect i)))
``````

Seems to be quite fast.

``````* (! 42)

1405006117752879898543142606244511569936384000000000
``````
-
Why don't you loop for i from 2 upto n, instead of from 2 below (+ n 1)? –  Svante Jan 11 '09 at 0:57

# Delphi iterative

While recursion can be the only decent solution to a problem, for factorials it is not. To describe it, yes. To program it, no. Iteration is cheapest.

This function calculates factorials for somewhat larger arguments.

``````function Factorial(aNumber: Int64): String;
var
F: Double;
begin
F := 0;
while aNumber > 1 do begin
F := F + log10(aNumber);
dec(aNumber);
end;
Result := FloatToStr(Power(10, Frac(F))) + ' * 10^' + IntToStr(Trunc(F));
end;
``````

1000000! = 8.2639327850046 * 10^5565708

-

Python:

Recursive

``````def fact(x):
return (1 if x==0 else x * fact(x-1))
``````

Using iterator

``````import operator

def fact(x):
return reduce(operator.mul, xrange(1, x+1))
``````
-

# Logo

``````? to factorial :n
> ifelse :n = 0 [output 1] [output :n * factorial :n - 1]
> end
``````

And to invoke:

``````? print factorial 5
120
``````

This is using the UCBLogo dialect of logo.

-

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...

-

# 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) }
``````

-

*NIX Shell

Linux version:

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

BSD version:

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

FORTH, iterative 1 liner

``````: FACT 1 SWAP 1 + 1 DO I * LOOP ;
``````
-

# 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.

-

C++

``````factorial(int n)
{
for(int i=1, f = 1; i<=n; i++)
f *= i;
return f;
}
``````
-

Java: functional

``````int factorial(int x) {
return x == 0 ? 1 : x * factorial(x-1);
}
``````
-

`````` fact 0 = 1
fact n = n * fact (n-1)
``````
-

This one not only calculates n!, it is also O(n!). It may have problems if you want to calculate anything "big" though.

``````long f(long n)
{
long r=1;
for (long i=1; i<n; i++)
r=r*i;
return r;
}

long factorial(long n)
{
// iterative implementation should be efficient
long result;
for (long i=0; i<f(n); i++)
result=result+1;
return result;
}
``````
-

Bourne Shell: Functional

``````factorial() {
if [ \$1 -eq 0 ]
then
echo 1
return
fi

a=`expr \$1 - 1`
expr \$1 \* `factorial \$a`
}
``````

Also works for Korn Shell and Bourne Again Shell. :-)

-