# Recursive algorithm to calculate square root

I have a code that calculates the square root of a number the following way:

``````void f1(int,int);

int main(){
int i=1;
int n;
scanf("%d",&n);
f1(n,i);
getch();
return 0;
}

void f1(int n,int i){
if((n*10000)-(i*i)<=0)
printf("%f",(double)i/100);
else
f1(n,i+1);
}
``````

I don't know why using `n*10000 - i*i`. Can someone explain this code please?

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Lets consider the example `n=100`. For the first bunch of recursions, we have `i=1,2,3,...`. Thus, for these calls, we have `n*10000 - i*i >= 0`. Then at some point we have `i=999` and observe that `n*10000 - 999*999 >= 0`. The next recursive step has `i=1000` and we see that `n*10000 - 1000*1000 <= 0`, so we print `(double)i / 100`, which is then just `10`. As you can see, the result is just the sqare root of `n=100`.

In general, the smallest number `i/100` satisfying `n*10000 - i*i <= 0` is "quite close" to the sqare root of `n`, because of the following:

``````sqrt(n*10000) = sqrt(n)*sqrt(10000) = sqrt(n)*100
``````

And we have:

``````n*10000 - i*i <= 0            | +i*i
n*10000 <= i*i          | sqrt both sides
sqrt(n)*100 <= i            | /100
sqrt(n) <= i/100
``````

Thus, we are looking for the smallest number `i/100` that is greater or equal to `sqrt(n)` and use this number as an approximation for `sqrt(n)`.

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@zubergu Doesn't it increase precision? If you worked without the multiplication, you obtain a plain integer `i` (in the mathematical sense), while - with multiplication - you (basically) can get a decimal number with two decimal places. – phimuemue Nov 12 '13 at 8:34
That's correct. – zubergu Nov 12 '13 at 8:37
@zubergu you could use n*100 and i/10 but its less accurate, so the error gets bigger – Stefan Nov 12 '13 at 8:38

you call the function with `n` and `i`, now as long as `i*i` is smaller than `n * 10000` you increase your `i`.

if your i*i is bigger than n * 10000 you print i / 100

eg: you call function with f1(1,1):

`````` 1*10000 >= 1*1 --> f1(1,2);
1*10000 >= 2*2 --> f1(1,3);
1*10000 >= 3*3 --> f1(1,4);
....
1*10000 >= 99*99 ->f1(1,100);
1*10000 <= 100*100 --> printf("%f",i/100.0); which gives: 1
``````

EDIT: another example, you look for the sqare root of 8: f1(8,1);

`````` 8*10000 >= 1*1 --> f1(8,2);
8*10000 >= 2*2 --> f1(8,3);
1*10000 >= 3*3 --> f1(8,4);
....
8*10000 >= 282*282 ->f1(8,283);
8*10000 <= 283*283 --> printf("%f",i/100.0); which gives: 2.83

and 2.83 * 2.83 = 8.0089
``````

EDIT: you may ask why n*10000, its because the calculation error gets smaller, eg: if you use n*100 and i/10 in the sqrt of 8 example you get

``````8*100 <= 29*29 --> 2.9
2.9 * 2.9 = 8.41 which is not good as 2.83 in the other example
``````
-

That is just to add some precision.

``````void f1(int n,int i){
printf("value of i is=%d \n",i);
if(n-i*i<=0)
printf("%f",i);
else
f1(n,i+1);
}
``````

this code will work for only perfect square numbers.

``````void f1(int n,int i){
printf("value of i is=%d \n",i);
if((n*100)-(i*i)<=0)
printf("%f",(double)i/10);
else
f1(n,i+1);
}
``````

this code will work for all numbers but will give result for just one digit after floating point.

``````void f1(int n,int i){
printf("value of i is=%d \n",i);
if((n*10000)-(i*i)<=0)
printf("%f",(double)i/100);
else
f1(n,i+1);
}
``````

this is your code which gives 2 digit point precision after floating point. so that (n*10000)-(i*i) is necessary as per your requirement. if you want to find for only perfect you can use first code too.

-

Consider this function:

``````void f1(int n,int i){
if((n)-(i*i)<=0)
printf("%f",i);
else
f1(n,i+1);
}
``````

This function would recursively loop over i until i^2 >=n, it's basically the same as doing this without recursion:

``````void f1(int n,int i){
int i = 1;
while (i*i < n)
++i;
printf("%f",i);
}
``````

Now the trick with the 10000 is just to add some precision emulated by large integers (note that it might overflow an int faster like that) - you calculate sqrt(100*100*n), which is 100*sqrt(n), so you divide the result by 100. This allows you to get a 2 digit precision.

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because it will　get the result rounded to two decimals.

for example, n=10 the result is 3.17.

and if you want to get result rounded to 3 decimals, you can write:

if((n*1000000)-(i*i)<=0) printf("%f",(double)i/1000);

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