The easiest solution, and I assume the one you're most likely to be looking for, is to calculate the axis-aligned bounding box, which is simply a case of finding the min/max x & y values, then constructing a box from those.

I'll give you pseudo-code for that, given that you haven't posted the types that your geometry is expressed in...

```
type point { float x; float y; }
type box { point topleft; point topright; point bottomleft; point
function bounding_box(points)
{
xmin = min(points.x)
xmax = max(points.x)
ymin = min(points.y)
ymax = max(points.y)
return new box{
topleft = { x = xmin, y = ymax },
topright = { x = xmax, y = ymax },
bottomleft = { x = xmin, y = ymin },
bottomright = { x = xmax, y = ymin }
};
}
```

So given these:

```
point[] points = [[x = -2, y = 0], [x = 1, y = 2], [x = 1, y = 1], [x = -1, y = -2]];
box bounds = bounding_box(points);
```

All of the following will be true:

```
bounds.topleft == [x = -2, y = 2];
bounds.topright == [x = 1, y = 2];
bounds.bottomleft == [x = -2, y = -2];
bounds.bottomright == [x = -1, y = -2];
```

Of course, if the coordinate system has the lowest coordinates at the top (e.g. like a typical display) - then you have to invert the calculation; or calculate the result in object-space first and then translate to logical space afterwards.

Notice I've gone for a type for the box that expresses all four corners, in case you decide in the future to update to an arbitrarily aligned box in the future (although by the same token you could just use a point + 2 vectors for that).