# smallest perimiter rectangle with given integer area and integer sides

Given an integer area A, how can one find integer sides w and h of a rectangle such that w*h = A and w+h is as small as possible? I'd rather the algorithm be simple than efficient (although within reasonable efficiency).

What would be the best way to accomplish this?

Finding out the prime factors of A, then combining them in some way that tries to balance w and h? Finding the two squares with integer sides with areas closest to A and then somehow interpolating between them? Any other method i'm not thinking of?

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You just need to find:

• The largest factor of A that is not greater than sqrt(A), and
• The smallest factor of A that is not less than sqrt(A)

The product of the two is always A, so these factors are your `w` and `h`

And of course you only need to search for one of them, because once you have `w` you just set `h = A / w`

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Here's something off the top off my head,

Start with `w=1; h=A;`

Then iterate over `w`, increasing it. After each increase of `w`, try decreasing `h` as long as `w*h>A`. Also, you'll need some kind of heuristic function that determines the size of a w/h-combination. Let's call it `size(x,y)`.

In each step you'll have to check if `size(w,h)<size(bestW,bestH)`, where `bestW` and `bestH` are the best values for `w` and `h` you encountered so far.

As far as the implementation of `size(x,y)` goes, you can `return x+y` or `return Math.abs(x-y)`

As you'll only have to keep increasing `w` until `w` >= `h` and initially `h=A` I'd guess the complexity is somewhere along the lines of `O(A/2) <= true complexity <= O(2A)`

And now to some pseudocode:

``````w=1;
h=A;

bestW=w;
bestH=h;

while(2*w<=A){
w++;
while(w*h>A) {
h--;
}
if(w*h==A && size(w,h)<size(bestW,bestH)){
bestW=w;
bestH=h;
}
}
``````
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