Let `W`

and `H`

be the width and height of the rectangle.

Let `s`

be the length of the side of a square.

Then the number of squares `n(s)`

that you can fit into the rectangle is `floor(W/s)*floor(H/s)`

. You want to find the maximum value of `s`

for which `n(s) >= N`

If you plot the number of squares against `s`

you will get a piecewise constant function. The discontinuities are at the values `W/i`

and `H/j`

, where `i`

and `j`

run through the positive integers.

You want to find the smallest `i`

for which `n(W/i) >= N`

, and similarly the smallest `j`

for which `n(H/j) >= N`

. Call these smallest values `i_min`

and `j_min`

. Then the largest of `W/i_min`

and `H/j_min`

is the `s`

that you want.

I.e. `s_max = max(W/i_min,H/j_min)`

To find `i_min`

and `j_min`

, just do a brute force search: for each, start from 1, test, and increment.

In the event that N is very large, it may be distasteful to search the `i`

's and `j`

's starting from 1 (although it is hard to imagine that there will be any noticeable difference in performance). In this case, we can estimate the starting values as follows. First, a ballpark estimate of the area of a tile is `W*H/N`

, corresponding to a side of `sqrt(W*H/N)`

. If `W/i <= sqrt(W*H/N)`

, then `i >= ceil(W*sqrt(N/(W*H)))`

, similarly `j >= ceil(H*sqrt(N/(W*H)))`

So, rather than start the loops at `i=1`

and `j=1`

, we can start them at `i = ceil(sqrt(N*W/H))`

and `j = ceil(sqrt(N*H/W)))`

. And OP suggests that `round`

works better than `ceil`

-- at worst an extra iteration.

Here's the algorithm spelled out in C++:

```
#include <math.h>
#include <algorithm>
// find optimal (largest) tile size for which
// at least N tiles fit in WxH rectangle
double optimal_size (double W, double H, int N)
{
int i_min, j_min ; // minimum values for which you get at least N tiles
for (int i=round(sqrt(N*W/H)) ; ; i++) {
if (i*floor(H*i/W) >= N) {
i_min = i ;
break ;
}
}
for (int j=round(sqrt(N*H/W)) ; ; j++) {
if (floor(W*j/H)*j >= N) {
j_min = j ;
break ;
}
}
return std::max (W/i_min, H/j_min) ;
}
```

The above is written for clarity. The code can be tightened up considerably as follows:

```
double optimal_size (double W, double H, int N)
{
int i,j ;
for (i = round(sqrt(N*W/H)) ; i*floor(H*i/W) < N ; i++){}
for (j = round(sqrt(N*H/W)) ; floor(W*j/H)*j < N ; j++){}
return std::max (W/i, H/j) ;
}
```