Looking for a really fast implementation of factorial function in JavaScript. Any suggests?

8What's the possible range of arguments? – Nikita Rybak Oct 18 '10 at 12:42

5Have you considered precalculating factorials and storing the values in a lookup table? – Waleed Amjad Oct 18 '10 at 12:43

2What's the application of such a function? In other words, what are you going to use it for? – Pointy Oct 18 '10 at 12:45

@Nikita Rybak, only 1 agrument (n). If (n > 170) e = Infinity – Ken Oct 18 '10 at 13:21

@ Pointy, yet another math calculator service. – Ken Oct 18 '10 at 13:22
You can search for (1...100)! on WolframAlpha to precalculate the factorial sequence.
The first 100 numbers are:
1, 2, 6, 24, 120, 720, 5040, 40320, 362880, 3628800, 39916800, 479001600, 6227020800, 87178291200, 1307674368000, 20922789888000, 355687428096000, 6402373705728000, 121645100408832000, 2432902008176640000, 51090942171709440000, 1124000727777607680000, 25852016738884976640000, 620448401733239439360000, 15511210043330985984000000, 403291461126605635584000000, 10888869450418352160768000000, 304888344611713860501504000000, 8841761993739701954543616000000, 265252859812191058636308480000000, 8222838654177922817725562880000000, 263130836933693530167218012160000000, 8683317618811886495518194401280000000, 295232799039604140847618609643520000000, 10333147966386144929666651337523200000000, 371993326789901217467999448150835200000000, 13763753091226345046315979581580902400000000, 523022617466601111760007224100074291200000000, 20397882081197443358640281739902897356800000000, 815915283247897734345611269596115894272000000000, 33452526613163807108170062053440751665152000000000, 1405006117752879898543142606244511569936384000000000, 60415263063373835637355132068513997507264512000000000, 2658271574788448768043625811014615890319638528000000000, 119622220865480194561963161495657715064383733760000000000, 5502622159812088949850305428800254892961651752960000000000, 258623241511168180642964355153611979969197632389120000000000, 12413915592536072670862289047373375038521486354677760000000000, 608281864034267560872252163321295376887552831379210240000000000, 30414093201713378043612608166064768844377641568960512000000000000, 1551118753287382280224243016469303211063259720016986112000000000000, 80658175170943878571660636856403766975289505440883277824000000000000, 4274883284060025564298013753389399649690343788366813724672000000000000, 230843697339241380472092742683027581083278564571807941132288000000000000, 12696403353658275925965100847566516959580321051449436762275840000000000000, 710998587804863451854045647463724949736497978881168458687447040000000000000, 40526919504877216755680601905432322134980384796226602145184481280000000000000, 2350561331282878571829474910515074683828862318181142924420699914240000000000000, 138683118545689835737939019720389406345902876772687432540821294940160000000000000, 8320987112741390144276341183223364380754172606361245952449277696409600000000000000, 507580213877224798800856812176625227226004528988036003099405939480985600000000000000, 31469973260387937525653122354950764088012280797258232192163168247821107200000000000000, 1982608315404440064116146708361898137544773690227268628106279599612729753600000000000000, 126886932185884164103433389335161480802865516174545192198801894375214704230400000000000000, 8247650592082470666723170306785496252186258551345437492922123134388955774976000000000000000, 544344939077443064003729240247842752644293064388798874532860126869671081148416000000000000000, 36471110918188685288249859096605464427167635314049524593701628500267962436943872000000000000000, 2480035542436830599600990418569171581047399201355367672371710738018221445712183296000000000000000, 171122452428141311372468338881272839092270544893520369393648040923257279754140647424000000000000000, 11978571669969891796072783721689098736458938142546425857555362864628009582789845319680000000000000000, 850478588567862317521167644239926010288584608120796235886430763388588680378079017697280000000000000000, 61234458376886086861524070385274672740778091784697328983823014963978384987221689274204160000000000000000, 4470115461512684340891257138125051110076800700282905015819080092370422104067183317016903680000000000000000, 330788544151938641225953028221253782145683251820934971170611926835411235700971565459250872320000000000000000, 24809140811395398091946477116594033660926243886570122837795894512655842677572867409443815424000000000000000000, 1885494701666050254987932260861146558230394535379329335672487982961844043495537923117729972224000000000000000000, 145183092028285869634070784086308284983740379224208358846781574688061991349156420080065207861248000000000000000000, 11324281178206297831457521158732046228731749579488251990048962825668835325234200766245086213177344000000000000000000, 894618213078297528685144171539831652069808216779571907213868063227837990693501860533361810841010176000000000000000000, 71569457046263802294811533723186532165584657342365752577109445058227039255480148842668944867280814080000000000000000000, 5797126020747367985879734231578109105412357244731625958745865049716390179693892056256184534249745940480000000000000000000, 475364333701284174842138206989404946643813294067993328617160934076743994734899148613007131808479167119360000000000000000000, 39455239697206586511897471180120610571436503407643446275224357528369751562996629334879591940103770870906880000000000000000000, 3314240134565353266999387579130131288000666286242049487118846032383059131291716864129885722968716753156177920000000000000000000, 281710411438055027694947944226061159480056634330574206405101912752560026159795933451040286452340924018275123200000000000000000000, 24227095383672732381765523203441259715284870552429381750838764496720162249742450276789464634901319465571660595200000000000000000000, 2107757298379527717213600518699389595229783738061356212322972511214654115727593174080683423236414793504734471782400000000000000000000, 185482642257398439114796845645546284380220968949399346684421580986889562184028199319100141244804501828416633516851200000000000000000000, 16507955160908461081216919262453619309839666236496541854913520707833171034378509739399912570787600662729080382999756800000000000000000000, 1485715964481761497309522733620825737885569961284688766942216863704985393094065876545992131370884059645617234469978112000000000000000000000, 135200152767840296255166568759495142147586866476906677791741734597153670771559994765685283954750449427751168336768008192000000000000000000000, 12438414054641307255475324325873553077577991715875414356840239582938137710983519518443046123837041347353107486982656753664000000000000000000000, 1156772507081641574759205162306240436214753229576413535186142281213246807121467315215203289516844845303838996289387078090752000000000000000000000, 108736615665674308027365285256786601004186803580182872307497374434045199869417927630229109214583415458560865651202385340530688000000000000000000000, 10329978488239059262599702099394727095397746340117372869212250571234293987594703124871765375385424468563282236864226607350415360000000000000000000000, 991677934870949689209571401541893801158183648651267795444376054838492222809091499987689476037000748982075094738965754305639874560000000000000000000000, 96192759682482119853328425949563698712343813919172976158104477319333745612481875498805879175589072651261284189679678167647067832320000000000000000000000, 9426890448883247745626185743057242473809693764078951663494238777294707070023223798882976159207729119823605850588608460429412647567360000000000000000000000, 933262154439441526816992388562667004907159682643816214685929638952175999932299156089414639761565182862536979208272237582511852109168640000000000000000000000, 93326215443944152681699238856266700490715968264381621468592963895217599993229915608941463976156518286253697920827223758251185210916864000000000000000000000000
If you still want to calculate the values yourself, you can use memoization:
var f = [];
function factorial (n) {
if (n == 0  n == 1)
return 1;
if (f[n] > 0)
return f[n];
return f[n] = factorial(n1) * n;
}
Edit: 21.08.2014
Solution 2
I thought it would be useful to add a working example of lazy iterative factorial function that uses big numbers to get exact result with memoization and cache as comparison
var f = [new BigNumber("1"), new BigNumber("1")];
var i = 2;
function factorial(n)
{
if (typeof f[n] != 'undefined')
return f[n];
var result = f[i1];
for (; i <= n; i++)
f[i] = result = result.multiply(i.toString());
return result;
}
var cache = 100;
// Due to memoization, following line will cache first 100 elements.
factorial(cache);
I assume you would use some kind of closure to limit variable name visibility.

Values past 6402373705728000 will be truncated so if you're going to use this approach make sure to convert to exponential before using the aforementioned table. – David Scott Kirby May 2 '14 at 20:36

1@DavidScottKirby Javascript automatically converts these numbers to their closest 64bit float representation. The real benefit of not having the full precision numbers in the code is reduced file size. – le_m Mar 9 '17 at 17:28

Your second solution could be simplified to
function factorial (n) { for (var i = f.length; i <= n; i++) f.push(f[i  1].multiply(i.toString())); return f[n]; }
Also see my answer which uses the more recent builtinBigInt
rather than a thirdparty library. – Patrick Roberts Oct 11 '19 at 16:30 
You should use a loop.
Here are two versions benchmarked by calculating the factorial of 100 for 10.000 times.
Recursive
function rFact(num)
{
if (num === 0)
{ return 1; }
else
{ return num * rFact( num  1 ); }
}
Iterative
function sFact(num)
{
var rval=1;
for (var i = 2; i <= num; i++)
rval = rval * i;
return rval;
}
Live at : http://jsfiddle.net/xMpTv/
My results show:
 Recursive ~ 150 milliseconds
 Iterative ~ 5 milliseconds..

+1 Great answer! Although memoization may be reasonable when there are multiple calls to calculate factorials for bigger numbers. – Tadeck Mar 19 '12 at 17:50

@Tadeck, thanks. Indeed memoization is very useful in this case and that is why Margus answer is picked as the correct one :) – Gabriele Petrioli Mar 19 '12 at 18:02

A 1line version of recursive: function factorial(num) { return (num == 1) ? num : num * arguments.callee(num1); } – jbyrd Oct 3 '14 at 16:05

2@HWTech, you are never calling the methods. Your test compares the speed of defining the two methods.. not the time they take to execute.. This is a better test (trying only the factorial of 15) – Gabriele Petrioli Oct 10 '14 at 9:58

4
I still think Margus's answer is the best one. However if you want to calculate the factorials of numbers within the range 0 to 1 (ie the gamma function) as well, then you cannot use that approach because the lookup table will have to contain infinite values.
However, you can approximate the values of the factorials, and it's pretty fast, faster than recursively calling itself or looping it at least (especially when values start to get bigger).
A good approximation method is Lanczos's one
Here is an implementation in JavaScript (ported from a calculator I wrote months ago):
function factorial(op) {
// Lanczos Approximation of the Gamma Function
// As described in Numerical Recipes in C (2nd ed. Cambridge University Press, 1992)
var z = op + 1;
var p = [1.000000000190015, 76.18009172947146, 86.50532032941677, 24.01409824083091, 1.231739572450155, 1.208650973866179E3, 5.395239384953E6];
var d1 = Math.sqrt(2 * Math.PI) / z;
var d2 = p[0];
for (var i = 1; i <= 6; ++i)
d2 += p[i] / (z + i);
var d3 = Math.pow((z + 5.5), (z + 0.5));
var d4 = Math.exp((z + 5.5));
d = d1 * d2 * d3 * d4;
return d;
}
You can now do cool stuff like factorial(0.41)
, etc however accuracy might be a little off, after all, it is an approximation of the result.



I recommend changing the part below the forloop to
var d3d4 = Math.exp((z + 0.5) * Math.log(z + 5.5)  z  5.5); return d1 * d2 * d3d4;
. This allows you to compute factorials up to 169! instead of currently only 140!. This is pretty close to the maximum representable factorial using theNumber
datatype, which is 170!. – le_m Mar 9 '17 at 19:22
Lookup table is the obvious way to go, if you're working with natural numbers. To calculate any factorial in realtime, you can speed it with a cache, saving the numbers you've calculated before. Something like:
factorial = (function() {
var cache = {},
fn = function(n) {
if (n === 0) {
return 1;
} else if (cache[n]) {
return cache[n];
}
return cache[n] = n * fn(n 1);
};
return fn;
})();
You can precalculate some values in order to speed it even more.

3I've created an automemoizer for any given function based on this answer (also slightly faster :)), also including a limit on the cache size. stackoverflow.com/a/10031674/36537 – Phil H Apr 5 '12 at 15:41
Here is my solution:
function fac(n){
return(n<2)?1:fac(n1)*n;
}
It's the simplest way (less characters / lines) I've found, only a function with one code line.
Edit:
If you really want to save some chars you can go with an Arrow Function (21 bytes):
f=n=>(n<2)?1:f(n1)*n

9

unfortunately even if it's nice to see and short in form, this is the slowest way to do it. – Zibri Sep 1 '19 at 14:40
Just One line with ES6
const factorial = n => !(n > 1) ? 1 : factorial(n  1) * n;
const factorial = n => !(n > 1) ? 1 : factorial(n  1) * n;
function print(value) {
document.querySelector('.result').innerHTML = value;
}
.result {
marginleft: 10px;
}
<input onkeyup="print(factorial(this.value))" type="number"/>
<span class="result">......</span>
short and easy recursive function (you could do it with a loop, too, but I don't think that would make any difference in performance):
function factorial (n){
if (n==0  n==1){
return 1;
}
return factorial(n1)*n;
}
for a very large n, you could use the stirlings approximation  but that will only give you an approximate value.
EDIT: a comment on why I'm getting a downvote for this would have been nice...
EDIT2: this would be the soulution using a loop (which would be the better choice):
function factorial (n){
j = 1;
for(i=1;i<=n;i++){
j = j*i;
}
return j;
}
I think the best solution would be to use the cached values, as Margus mentioned and use the stirlings approximation for larger values (assumed you have to be realy fast and don't have to be that exact on such big numbers).

4In languages without tail call optimisation (i.e. most widelyused languages) it is better to use a nonrecursive implementation where it is easy to do so, though there are ways around it: paulbarry.com/articles/2009/08/30/tailcalloptimization – Daniel Earwicker Oct 18 '10 at 12:57

that's indeed definitely not that fastest, as it wouldn't even use TCO, if it were implemented. But it is simple and I wouldn't downvote it. It's not the fastest for sure. – haylem Oct 18 '10 at 13:02

Tail call optimization isn't even possible for this function, as the recursive call is not in tail position. – Fred Foo Oct 18 '10 at 13:03

3@Josh, (not the downvoter) fastest is the loop by quite a margin .. – Gabriele Petrioli Oct 18 '10 at 13:04
Behold, the memoizer, which takes any singleargument function and memoizes it. Turns out to be marginally faster than @xPheRe's solution, including the limit on the size of the cache and associated checking, because I use shortcircuiting and so on.
function memoize(func, max) {
max = max  5000;
return (function() {
var cache = {};
var remaining = max;
function fn(n) {
return (cache[n]  (remaining >0 ? (cache[n]=func(n)) : func(n)));
}
return fn;
}());
}
function fact(n) {
return n<2 ? 1: n*fact(n1);
}
// construct memoized version
var memfact = memoize(fact,170);
// xPheRe's solution
var factorial = (function() {
var cache = {},
fn = function(n) {
if (n === 0) {
return 1;
} else if (cache[n]) {
return cache[n];
}
return cache[n] = n * fn(n 1);
};
return fn;
}());
Approximately 25x faster on my machine in Chrome than the recursive version, and 10% faster than xPheRe's.
Fastest factorial function
I think that this loopbased version might be the fastest factorial function.
function factorial(n, r = 1) {
while (n > 0) r *= n;
return r;
}
// Default parameters `r = 1`,
// was introduced in ES6
And here is my reasoning:
 Recursive functions, even with memoization, have the overhead of a function call (basically pushing functions onto the stack) which is less performant than using a loop
 While
for
loops andwhile
loops have similar performance, afor
loop without an initializationexpression and finalexpression looks odd; probably better to writefor(; n > 0;)
aswhile(n > 0)
 Only two parameters
n
andr
are used, so in theory less parameters means less time spent allocating memory  Uses a decremented loop which checks if
n
is zero  I've heard theories that computers are better at checking binary numbers (0 and 1) than they are at checking other integers
I came across this post. Inspired by all contributions here I came up with my own version, which has two features that I haven't seen discussed before: 1) A check to ensure the argument is a nonnegative integer 2) Making a unit out of the cache and the function to make it one self contained bit of code. For fun, I tried to make it as compact as possible. Some may find that elegant, others may think it terribly obscure. Anyway, here it is:
var fact;
(fact = function(n){
if ((n = parseInt(n)) < 0  isNaN(n)) throw "Must be nonnegative number";
var cache = fact.cache, i = cache.length  1;
while (i < n) cache.push(cache[i++] * i);
return cache[n];
}).cache = [1];
You can either pre fill the cache, or allow it to be filled as the calls go by. But the initial element (for fact(0) must be present or it will break.
Enjoy :)
It is very simple using ES6
const factorial = n => n ? (n * factorial(n1)) : 1;
See an example here
Here is one solution:
function factorial(number) {
total = 1
while (number > 0) {
total *= number
number = number  1
}
return total
}
Using ES6 you can achieve it both fast and short:
const factorial = n => [...Array(n + 1).keys()].slice(1).reduce((acc, cur) => acc * cur, 1)
The code to calculate factorial depends on your requirements.
 Are you concerned about overflow?
 What range of inputs will you have?
 Is it more important for you to minimize size or time?
 What are you going to do with the factorial?
Regarding points 1 and 4, it is often more useful to have a function to evaluate the log of the factorial directly rather than to have a function to evaluate factorial itself.
Here's a blog post that discusses these issues. Here is some C# code for computing log factorial that would be trivial to port to JavaScript. But it may not be best for your needs depending on your answers to the questions above.

Numbered list probably should be in comments. All that's left is two links, and linkonly answers are discouraged. – Barett Aug 24 '15 at 21:20
This is a compact loopbased version
function factorial( _n )
{
var _p = 1 ;
while( _n > 0 ) { _p *= _n ; }
return _p ;
}
Or you might override Math object (recursive version):
Math.factorial = function( _x ) { return _x <= 1 ? 1 : _x * Math.factorial( _x ) ; }
Or join both approaches ...

1
Exploiting the fact that Number.MAX_VALUE < 171!
, we can simply use a complete lookup table consisting of just 171 compact array elements taking up less than 1.4 kilobytes of memory.
A fast lookup function with runtime complexity O(1) and minimal array access overhead would then look as follows:
// Lookup table for n! for 0 <= n <= 170:
const factorials = [1,1,2,6,24,120,720,5040,40320,362880,3628800,39916800,479001600,6227020800,87178291200,1307674368e3,20922789888e3,355687428096e3,6402373705728e3,121645100408832e3,243290200817664e4,5109094217170944e4,1.1240007277776077e21,2.585201673888498e22,6.204484017332394e23,1.5511210043330986e25,4.0329146112660565e26,1.0888869450418352e28,3.0488834461171387e29,8.841761993739702e30,2.6525285981219107e32,8.222838654177922e33,2.631308369336935e35,8.683317618811886e36,2.9523279903960416e38,1.0333147966386145e40,3.7199332678990125e41,1.3763753091226346e43,5.230226174666011e44,2.0397882081197444e46,8.159152832478977e47,3.345252661316381e49,1.40500611775288e51,6.041526306337383e52,2.658271574788449e54,1.1962222086548019e56,5.502622159812089e57,2.5862324151116818e59,1.2413915592536073e61,6.082818640342675e62,3.0414093201713376e64,1.5511187532873822e66,8.065817517094388e67,4.2748832840600255e69,2.308436973392414e71,1.2696403353658276e73,7.109985878048635e74,4.0526919504877214e76,2.3505613312828785e78,1.3868311854568984e80,8.32098711274139e81,5.075802138772248e83,3.146997326038794e85,1.98260831540444e87,1.2688693218588417e89,8.247650592082472e90,5.443449390774431e92,3.647111091818868e94,2.4800355424368305e96,1.711224524281413e98,1.1978571669969892e100,8.504785885678623e101,6.1234458376886085e103,4.4701154615126844e105,3.307885441519386e107,2.48091408113954e109,1.8854947016660504e111,1.4518309202828587e113,1.1324281178206297e115,8.946182130782976e116,7.156945704626381e118,5.797126020747368e120,4.753643337012842e122,3.945523969720659e124,3.314240134565353e126,2.81710411438055e128,2.4227095383672734e130,2.107757298379528e132,1.8548264225739844e134,1.650795516090846e136,1.4857159644817615e138,1.352001527678403e140,1.2438414054641308e142,1.1567725070816416e144,1.087366156656743e146,1.032997848823906e148,9.916779348709496e149,9.619275968248212e151,9.426890448883248e153,9.332621544394415e155,9.332621544394415e157,9.42594775983836e159,9.614466715035127e161,9.90290071648618e163,1.0299016745145628e166,1.081396758240291e168,1.1462805637347084e170,1.226520203196138e172,1.324641819451829e174,1.4438595832024937e176,1.588245541522743e178,1.7629525510902446e180,1.974506857221074e182,2.2311927486598138e184,2.5435597334721877e186,2.925093693493016e188,3.393108684451898e190,3.969937160808721e192,4.684525849754291e194,5.574585761207606e196,6.689502913449127e198,8.094298525273444e200,9.875044200833601e202,1.214630436702533e205,1.506141741511141e207,1.882677176888926e209,2.372173242880047e211,3.0126600184576594e213,3.856204823625804e215,4.974504222477287e217,6.466855489220474e219,8.47158069087882e221,1.1182486511960043e224,1.4872707060906857e226,1.9929427461615188e228,2.6904727073180504e230,3.659042881952549e232,5.012888748274992e234,6.917786472619489e236,9.615723196941089e238,1.3462012475717526e241,1.898143759076171e243,2.695364137888163e245,3.854370717180073e247,5.5502938327393044e249,8.047926057471992e251,1.1749972043909107e254,1.727245890454639e256,2.5563239178728654e258,3.80892263763057e260,5.713383956445855e262,8.62720977423324e264,1.3113358856834524e267,2.0063439050956823e269,3.0897696138473508e271,4.789142901463394e273,7.471062926282894e275,1.1729568794264145e278,1.853271869493735e280,2.9467022724950384e282,4.7147236359920616e284,7.590705053947219e286,1.2296942187394494e289,2.0044015765453026e291,3.287218585534296e293,5.423910666131589e295,9.003691705778438e297,1.503616514864999e300,2.5260757449731984e302,4.269068009004705e304,7.257415615307999e306];
// Lookup function:
function factorial(n) {
return factorials[n]  (n > 170 ? Infinity : NaN);
}
// Test cases:
console.log(factorial(NaN)); // NaN
console.log(factorial(Infinity)); // NaN
console.log(factorial(1)); // NaN
console.log(factorial(0)); // 1
console.log(factorial(170)); // 7.257415615307999e+306 < Number.MAX_VALUE
console.log(factorial(171)); // Infinity > Number.MAX_VALUE
console.log(factorial(Infinity)); // Infinity
This is as precise and as fast as it gets using the Number
datatype. Computing the lookup table in Javascript  as some other answers suggest  will reduce precision when n! > Number.MAX_SAFE_INTEGER
.
Compressing the runtime table via gzip reduces its size on disk from about 3.6 to 1.8 kilobytes.
One line answer:
const factorial = (num, accumulator) => num <= 1 ? accumulator  1 : factorial(num, num * (accumulator  num + 1));
factorial(5); // 120
factorial(10); // 3628800
factorial(3); // 6
factorial(7); // 5040
// et cetera
Iterative factorial with BigInt
for safety
Solution uses
BigInt
, an ES 2018+/2019 feature.
This is working example uses BigInt
, because many answers here all escape the safe boundary of Number
(MDN) almost right away. It's not the fastest but it's simple and thus clearer for adapting other optimizations (like a cache of the first 100 numbers).
function factorial(nat) {
let p = BigInt(1)
let i = BigInt(nat)
while (1 < i) p *= i
return p
}
Example Usage
// 9.332621544394415e+157
Number(factorial(100))
// "933262154439441526816992388562667004907159682643816214685929638952175999
// 932299156089414639761565182862536979208272237582511852109168640000000000
// 00000000000000"
String(factorial(100))
// 9332621544394415268169923885626670049071596826438162146859296389521759999
// 3229915608941463976156518286253697920827223758251185210916864000000000000
// 000000000000n
factorial(100)
 The
n
at the end of a numeric literal like1303n
indicates it's aBigInt
type.  Remember that you shouldn't mix
BigInt
withNumber
unless you explicitly coerce them, and that doing so could cause a loss in accuracy.
Just for completeness, here is a recursive version that would allow tail call optimization. I'm not sure if tail call optimizations are performed in JavaScript though..
function rFact(n, acc)
{
if (n == 0  n == 1) return acc;
else return rFact(n1, acc*n);
}
To call it:
rFact(x, 1);

ES6 supports TCO, but afaik this feature isn't active per default in any major engine yet – le_m Mar 18 '17 at 22:31
This is an iterative solution that uses less stack space and save previously computed values in a selfmemoizing way:
Math.factorial = function(n){
if(this.factorials[n]){ // memoized
return this.factorials[n];
}
var total=1;
for(var i=n; i>0; i){
total*=i;
}
this.factorials[n] = total; // save
return total;
};
Math.factorials={}; // store
Also note that I am adding this to the Math object which is an object literal so there is no prototype. Rather just binding these to the function directly.

This doesn't really take full advantage of the memoization for subproblems  for example,
Math.factorial(100); Math.factorial(500);
will calculate the 1..100 multiplication twice. – Barett Aug 24 '15 at 21:13
I believe the following is the most sustainable and efficient piece of code from the comments above. You can use this in your global application js architecture... and, not worry about writing it in multiple namespaces (since its a task which probably doesn't need much augmenting). I've included 2 method names (based on preference) but both can be used as they're just references.
Math.factorial = Math.fact = function(n) {
if (isNaN(n)n<0) return undefined;
var f = 1; while (n > 1) {
f *= n;
} return f;
};

By starting your multiplication with
n * (n1) * (n2) * ... * 1
instead of the other way round, you loose up to 4 digits in precision for n >> 20. – le_m Mar 9 '17 at 20:16
// if you don't want to update the Math object, use `var factorial = ...`
Math.factorial = (function() {
var f = function(n) {
if (n < 1) {return 1;} // no real error checking, could add typecheck
return (f[n] > 0) ? f[n] : f[n] = n * f(n 1);
}
for (i = 0; i < 101; i++) {f(i);} // precalculate some values
return f;
}());
factorial(6); // 720, initially cached
factorial[6]; // 720, same thing, slightly faster access,
// but fails above current cache limit of 100
factorial(100); // 9.33262154439441e+157, called, but pulled from cache
factorial(142); // 2.6953641378881614e+245, called
factorial[141]; // 1.89814375907617e+243, now cached
This does the caching of the first 100 values on the fly, and does not introduce an external variable into scope for the cache, storing the values as properties of the function object itself, which means that if you know factorial(n)
has already been calculated, you can simply refer to it as factorial[n]
, which is slightly more efficient. Running these first 100 values will take submillisecond time in modern browsers.


@AutoSponge That's because
21! > Number.MAX_SAFE_INTEGER
, thus cannot safely be represented as a 64bit float. – le_m Mar 9 '17 at 21:25
Here is an implementation which calculates both positive and negative factorials. It's fast and simple.
var factorial = function(n) {
return n > 1
? n * factorial(n  1)
: n < 0
? n * factorial(n + 1)
: 1;
}

Usually, n! for n < 0 is not defined. See mathoverflow.net/questions/10124/thefactorialof123 – le_m Mar 9 '17 at 21:24
Here's one I made myself, don't use numbers over 170 or under 2.
function factorial(x){
if((!(isNaN(Number(x)))) && (Number(x)<=170) && (Number(x)>=2)){
x=Number(x);for(i=x(1);i>=1;i){
x*=i;
}
}return x;
}

By starting your multiplication with n * (n1) * (n2) * ... * 1 instead of the other way round, you loose up to 4 digits in precision for n >> 20. Also, creates an unwanted global variable
i
and performs way too manyNumber
conversions and gives incorrect results for 0! (as you stated, but why?). – le_m Mar 9 '17 at 21:15
Here is my code
function factorial(num){
var result = num;
for(i=num;i>=2;i){
result = result * (i1);
}
return result;
}

1If (n > 170) e = Infinity . And your code will generate a huge number. wont there be any overflows ? – prime Jan 3 '14 at 17:12

Incorrect result for
factorial(0)
. Also, by starting your multiplication with n * (n1) * (n2) * ... * 1 instead of the other way round, you loose up to 4 digits in precision for n >> 20. @prime:170! > Number.MAX_VALUE
and is best represented withInfinity
. – le_m Mar 9 '17 at 21:20
Cached loop should be fastest (at least when called multiple times)
var factorial = (function() {
var x =[];
return function (num) {
if (x[num] >0) return x[num];
var rval=1;
for (var i = 2; i <= num; i++) {
rval = rval * i;
x[i] = rval;
}
return rval;
}
})();
function isNumeric(n) {
return !isNaN(parseFloat(n)) && isFinite(n)
}
Provided by http://javascript.info/tutorial/numbermath as a simple way to evaluate if an object is a proper integer for calculation.
var factorials=[[1,2,6],3];
A simple set of Memoized factorials that require redundant calculations, may be processed with "multiply by 1", or are one digit that is a simple equation not worth processing live.
var factorial = (function(memo,n) {
this.memomize = (function(n) {
var ni=n1;
if(factorials[1]<n) {
factorials[0][ni]=0;
for(var factorial_index=factorials[1]1;factorials[1]<n;factorial_index++) {
factorials[0][factorials[1]]=factorials[0][factorial_index]*(factorials[1]+1);
factorials[1]++;
}
}
});
this.factorialize = (function(n) {
return (n<3)?n:(factorialize(n1)*n);
});
if(isNumeric(n)) {
if(memo===true) {
this.memomize(n);
return factorials[0][n1];
}
return this.factorialize(n);
}
return factorials;
});
After reviewing the input from other members (excluding the Log advice, although I may implement that later) I went ahead and threw together a script that is fairly simple. I started with a simple uneducated JavaScript OOP example and built a little class to handle factorials. I then implemented my version of the Memoization that was suggested above. I also implemented the shorthand Factorialization however I made a small error adjustment; I changed the "n<2" to "n<3". "n<2" would still process n=2 which would be a waste, because you would iterate for a 2*1=2; this is a waste in my opinion. I altered it to "n<3"; because if n is 1 or 2 it will simply return n, if it is 3 or more it will evaluate normally. Of course as rules apply, I placed my functions in descending order of assumed execution. I added in the bool(truefalse) option to allow quick altering between memo'ed and normal execution (You just never know when you want to swap around on your page without needing to change the "style") As I said before the memoized factorials variable is set with the 3 starting positions, taking 4 characters, and minimizing wasteful calculations. Everything past the third iteration you are handling double digit math plus. I figure if you where a stickler enough about it you would run on a factorial table (as implemented).
What have I planned after this? local&session storage to allow for a case by case cache of needed iterations, essentially handling the "table" issue spoken above. This would also massively save database and server side space. However, if you go with localStorage you would essentially be sucking up space on your users computer simply to store a list of numbers and make their screen LOOK faster, however over a long period of time with an immense need this would be slow. I am thinking sessionStorage (clearing after Tab leaves) would be a much better route. Possibly combine this with a self balancing server/local dependent cache? User A needs X iterations. User B need Y iterations. X+Y/2=Amount needed locally cached. Then just detect and fiddle with loadtime and executetime benchmarks live for every user until it adjusts itself to optimization for the site itself. Thanks!
Edit 3:
var f=[1,2,6];
var fc=3;
var factorial = (function(memo) {
this.memomize = (function(n) {
var ni=n1;
if(fc<n) {
for(var fi=fc1;fc<n;fi++) {
f[fc]=f[fi]*(fc+1);
fc++;
}
}
return f[ni];
});
this.factorialize = (function(n) {
return (n<3)?n:(factorialize(n1)*n);
});
this.fractal = (function (functio) {
return function(n) {
if(isNumeric(n)) {
return functio(n);
}
return NaN;
}
});
if(memo===true) {
return this.fractal(memomize);
}
return this.fractal(factorialize);
});
This edit implements another Stack suggestion and allows me to call the function as factorial(true)(5), which was one of my goals setting out. :3 I also removed some needless assigning, and shorthanded some nonpublic variable names.

Returns
undefined
for 0!. ES6 allows to replaceisNumeric
withNumber.isInteger
. Lines likefactorials[0][factorials[1]]=factorials[0][factorial_index]*(factorials[1]+1);
are totally unreadable. – le_m Mar 9 '17 at 20:56
Here is one using newer javascript functions fill, map, reduce and constructor (and fat arrow syntax):
Math.factorial = n => n === 0 ? 1 : Array(n).fill(null).map((e,i)=>i+1).reduce((p,c)=>p*c)
Edit: updated to handle n === 0

2

1That's a neat idea. Rather than traversing the length twice, why not convert all the logic to the reduce function and use it's initial value to handle edge case
n === 0
?Math.factorial = n => Array.from({ length: n }).reduce((product, _, i) => product * (i + 1), 1)
– AlexSashaRegan Sep 20 '17 at 4:30
function computeFactorialOfN(n) {
var output=1;
for(i=1; i<=n; i++){
output*=i;
} return output;
}
computeFactorialOfN(5);

2Welcome to StackOverflow and thanks for your help. You might want to make your answer even better by adding some explanation. – Elias MP Aug 29 '17 at 11:32
According to Wolfram MathWorld:
The factorial n! is defined for a positive integer n as
Therefore, you can use the following method to obtain the factorial of a number:
const factorial = n => +!n  n * factorial(n);
factorial(4) // 4! = 4 * 3 * 2 * 1 = 24