# JavaScript - Improving algorithm for finding square roots of perfect squares without Math.sqrt

I'm trying to learn algorithms and coding stuff by scratch. I wrote a function that will find square roots of square numbers only, but I need to know how to improve its performance and possibly return square roots of non square numbers

``````function squareroot(number) {
var number;
for (var i = number; i >= 1; i--) {
if (i * i === number) {
number = i;
break;
}
}
return number;
}

alert(squareroot(64))
``````

Will return 8

Most importantly I need to know how to improve this performance. I don't really care about its limited functionality yet

• What happens for `squareroot(65)`? Hint: nothing good. – Bergi Mar 7 '16 at 22:57
• ` I need to know how to improve its performance` what makes you think it doesn't have "good" performance? What are your benchmarks? People talk in general terms of performance but that's all it is general terms. What are you trying to improve? – scrappedcola Mar 7 '16 at 22:57
• `var squareroot = Math.sqrt;` there I did it for you – Matti Virkkunen Mar 7 '16 at 22:58
• It seems I'm iterating over every possible number and that might be unnecessary – user5680735 Mar 7 '16 at 22:58
• There are pretty many quite sophisticated algorithms to do this. You won't benefit from most of these as a learner, though. – Bergi Mar 7 '16 at 22:59

## 5 Answers

Here is a small improvement I can suggest. First - start iterating from 0. Second - exit loop when the square of root candidate exceeds the `number`.

``````function squareroot(number) {
for (var i = 0; i * i <= number; i++) {
if (i * i === number)
return i;
}
return number; // don't know if you should have this line in case nothing found
}
``````

This algo will work in O(√number) time comparing to initial O(n) which is indeed performance improvement that you asked.

Edit #1

Just even more efficient solution would be to binary search the answer as @Spektre suggested. It is known that x2 is increasing function.

``````function squareroot(number) {
var lo = 0, hi = number;
while(lo <= hi) {
var mid = Math.floor((lo + hi) / 2);
if(mid * mid > number) hi = mid - 1;
else lo = mid + 1;
}
return hi;
}
``````

This algo has O(log(number)) running time complexity.

• @user5680735 this runs in `O(n)` if you change the for a little to scan the bits from MSB to LSB you will get binary search which runs in `O(log(n))` instead. the code will change just slightly see my linked QA's I commented your Question with – Spektre Mar 8 '16 at 9:24
• @Spektre, where did you found a `sqrt` function usage? I've changed O(sqrt(number)) notation not to confuse you. – Ivan Gritsenko Mar 8 '16 at 9:34
• Sorry my bad... You gave it right. I still did not have my tea in the morning ... I saw it in `O(sqrt(number))` miss the `O` :) – Spektre Mar 8 '16 at 10:24

The stuff that you try to do is called numerical methods. The most rudimentary/easy numerical method for equation solving (yes, you solve an equation x^2 = a here) is a Newtons method.

All you do is iterate this equation: In your case `f(x) = x^2 - a` and therefore `f'(x) = 2x`.

This will allow you to find a square root of any number with any precision. It is not hard to add a step which approximate the solution to an integer and verifies whether `sol^2 == a`

• Thanks for your answer. But what is `a`? I found in preudocode on Wikipedia Newton's method page that `f = @(x) x^2 - 2 %The function whose root we are trying to find` and can't understand why `... - 2` here – Mikhail May 13 '18 at 12:38
• @Mikhail `a` is the number which square root you are trying to find. So if you want to find a sqrt(15), then `a=15` – Salvador Dali May 13 '18 at 20:27

Separates Newton's method from the function to approximate. Can be used to find other roots.

``````function newton(f, fPrime, tolerance) {
var x, first;

return function iterate(n) {
if (!first) { x = n; first = 1; }

var fn = f(x);

var deltaX = fn(n) / fPrime(n);
if (deltaX > tolerance) {
return iterate(n - deltaX)
}

first = 0;
return n;
}
}

function f(n) {
return  function(x) {
if(n < 0) throw n + ' is outside the domain of sqrt()';
return x*x - n;
};
}

function fPrime(x) {
return 2*x;
}

var sqrt = newton(f, fPrime, .00000001)
console.log(sqrt(2))
console.log(sqrt(9))
console.log(sqrt(64))
``````

Binary search will work best.

``````let number = 29;
let res = 0;

console.log((square_root_binary(number)));
function square_root_binary(number){

if (number == 0 || number == 1)
return number;

let start = 0;
let end = number;

while(start <= end){

let mid = ( start + end ) / 2;

mid = Math.floor(mid);

if(mid * mid == number){
return mid;
}

if(mid * mid < number){
start = mid + 1;
res = mid;
}
else{
end = mid - 1;
}
}

return res;
}
``````
``````function squareRoot(n){
var avg=(a,b)=>(a+b)/2,c=5,b;
for(let i=0;i<20;i++){
b=n/c;
c=avg(b,c);
}
return c;
}
``````

This will return the square root by repeatedly finding the average.

``````var result1 = squareRoot(25) //5
var result2 = squareRoot(100) //10
var result3 = squareRoot(15) //3.872983346207417
``````

JSFiddle: https://jsfiddle.net/L5bytmoz/12/